iv. cerebrovascular diseases - judoctors disease denotes brain disorders caused by pathologic...
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IV. Cerebrovascular diseases
- Cerebrovascular disease denotes brain disorders caused by pathologic processes involving the blood vessels.
- The three main pathogenic mechanisms are:
1. Thrombotic occlusion of vessels
2. Embolic occlusion of vessels
3. Vascular rupture.
- Thrombosis and embolism cause ischemic injury or infarction of specific regions of the brain, depending on the vessel involved.
- Hemorrhage accompanies rupture of vessels, leading to direct tissue damage as well as secondary ischemic injury
Stroke :
- Is the clinical designation applied to
a. Abrupt onset of focal or global neurological
symptoms
b. caused by ischemia or hemorrhage
c. and these symptoms must continue for more
than 24 hours
d. and there should be permanent damage to the
brain.
Transient ischemic attack(TIA):
a- Applied that the neurological symptoms resolve
within 24 hours
b. No irreversible tissue damage
c. The cause is small emboli from the carotids or
vertebrobasilar circulation that resolve before
causing irreversible injury
Example Amarex fugax
- From the standpoint of the pathophysiologyand pathologic anatomy, it is convenient to consider cerebrovascular disease as two processes
a. Hypoxia, ischemia and infarction
b. Hemorrhage
A. Hypoxia, ischemia and infarction
- The brain may be deprived of oxygen by several mechanisms
a. Functional hypoxia in a setting of a low partial pressure of oxygen or impaired oxygen-carrying capacity
b. Global Ischemia; either transient or permanent due to tissue hypoperfusion, which can be caused by, hypotension or shock
c. Vascular obstruction.
I. Global ischemia
- Widespread ischemic injury can occur in the setting
of severe systemic hypotension, when systolic
pressure fall below 50 mm Hg such as in cardiac
arrest, and shock because of failure of
autoregulation
- The clinical outcome varies with the severity and
duration of the insult
A. Mild transient Global Ischemia
- There may be only a transient postischemic
confusional state, with eventual complete
recovery.
- Neurons are more susceptible to mild ischemic
injury than glial cells
- Neurons are the most susceptible followed by
oligodendrocytes , astocytes then endothelial cells
- The most susceptible neurons to mild transient
global ischemia are:
1. The pyramidal cells of the CA1 region of the
hippocampus
2. Middle cortical lamina of the neocortex , layers 3, 5,
and 6 (called laminar necrosis)
3. Purkinje cells of the cerebellum.
Note:
- Neuronal loss in transient global ischemia is due to excitotoxicity
- The susceptible neurons have many receptors to the excitatory neurotransmitter glutamate
- So in transient global ischemia, the astrocytesrelease glutamate that binds to its neuronal receptors NMDA (N-methyl D-aspartate) leading to increase intracellular calcium and activation of enzymes that leads to death of these neurons
B. Severe global ischemia
- Widespread neuronal death occurs irrespective of regional vulnerability.(pan necrosis)
a. Persistent vegetative state ( awake but not aware)
- In severe global cerebral ischemia, individuals who survive in this state often remain severely impaired neurologically.
b. Brain death
- Other patients meet the clinical criteria for "brain death," including:
1. Evidence of diffuse cortical injury (isoelectric, or "flat," electroencephalogram
2. And brain stem damage, including absent reflexes and respiratory drive.
. Border zone ("watershed") infarcts
- Are wedge-shaped areas of infarction that occur in those regions of the brain and spinal cord that lie at the most distal fields of arterial perfusion.
"- In the cerebral hemispheres, the border zone between the anterior and the middle cerebral artery distributions is at greatest risk(double watershed area).
- Damage to this region produces a band of necrosis over the cerebral convexity a few centimeters lateral to the inter-hemispheric fissure.
- Border zone infarcts are usually seen after hypotensive episodes.
.
2. Focal Cerebral Ischemia
- Cerebral arterial occlusion leads to focal ischemia and-if sustained-to infarction of CNS tissue in the distribution of the compromised vessel.
- The size, location, and shape of the infarct and the extent of tissue damage that results are determined by modifying variables, most importantly the adequacy of collateral flow
- The major source of collateral flow is the circle of Willis.
- Partial collateralization is also provided over the surface of the brain through cortical-leptomeningealanastomoses.
• NOTE
- In contrast, there is little if any collateral flow for thalamus, basal ganglia, and deep white matter which are supplied by deep penetrating vessels.
- Occlusive vascular disease of severity sufficient to lead to cerebral infarction may be due to
1. In situ thrombosis
- The majority of thrombotic occlusions causing cerebral infarctions are due to atherosclerosis
- The most common sites of primary thrombosis are
a. The carotid bifurcation,
b. The origin of the middle cerebral artery,
c. And at either end of the basilar artery
- The venous side of the circulation may also
undergo thrombosis and cause significant
cerebral ischemia
- The striking example is the thrombosis of the
superior sagittal sinus which can occur with
infections or hypercoagulability state
2. Embolization from a distant source.
- Overall, embolic infarctions are more common than thrombosis.
- Sources of emboli:
a. Cardiac mural thrombi are a frequent source
b. Thromboemboli also arise in arteries, most often from atheromatous plaques within the carotid arteries.
c. Paradoxical emboli, particularly in children with cardiac anomalies;
d. Emboli of other materials (tumor, fat, or air).
NOTES- The territory of distribution of the middle cerebral
artery-the direct extension of the internal carotid artery-is most frequently affected by embolic infarction;
- Emboli tend to lodge where vessels branch or in areas of pre-existing luminal stenosis
- Infarcts can be divided into two broad groups hemorrhagic and non-hemorrhagic based on their macroscopic and corresponding radiologic appearance
Microscopically,
1. After the first 12 hours:
a. Red neurons and both cytotoxic and vasogenicedema predominate
b. Swelling of endothelial and glial cells, mainly astrocytes
d. Disintegration and myelinated fibers .
2. Up to 48 hours, there is some neutrophilicemigration
3. 2-3 weeks
a. Mononuclear phagocytic cells predominate and macrophages containing myelin breakdown products or blood may persist in the lesion for months to years.
b. As the process of phagocytosis and liquefaction proceeds, ---there will be gemistocytic gliosis
4. After several months :
- Fibrillary astrocytosis
Notes:
a. In the cerebral cortex the cavity is delimited from the meninges and subarachnoid space by a glioticlayer of tissue, derived from the molecular layer of cortex.
b- The pia and arachnoid are not affected and do not contribute to the healing process.
Cerebral infarction
B. Intracranial Hemorrhage-- Hemorrhage within the skull can occur in a variety
of locations, and each location is associated with a set of underlying causes.
1. Hemorrhages within the brain itself can occur:a. Secondary to hypertension (most common)b. Cerebral amyloid angiopathyc. Arterio-venous malformation, d. A cavernous malformation, or e.. An intra-parenchymal tumor especially
oligodendroglioma, glioblastoma or metastaicrenal cell carcinoma and melanoma.
2. Subarachnoid hemorrhages:
- Are most commonly seen with aneurysms but occur also with other vascular malformations.
3. Hemorrhages associated with the dura (in either subdural or epidural spaces) usually due to trauma.
1. Primary Brain Parenchymal Hemorrhage
- Spontaneous (non-traumatic) intra-parenchymalhemorrhages occur most commonly in mid to late adult life, with a peak incidence at about 60 years of age
- Most are caused by rupture of a small intraparenchymal vessel
A. Hypertension :
- Is the leading underlying cause, and brain
hemorrhage accounts for roughly 15% of deaths
among persons with chronic hypertension
- It has a peak incidence at about 60 years
- Intracerebral hemorrhage can be clinically
devastating when it affects large portions of the
brain or extends into ventricular system or, it can
affect small regions and be clinically silent.
- Massive Hypertensive intraparenchymal
hemorrhages occur in:
a. Basal ganglia,--most common location
b. Thalamus
c. Pons
d. and Cerebellum
Mechanisms of massive hemorrhage in Hypertension:
1. Hyaline arteriolar sclerosis
- Affects the deep penetrating arteries and arterioles
that supply the basal ganglia and the brain stem
- Affected arteriolar walls are weakened and are
more vulnerable to rupture
2. Chronic hypertension results in formation of minute
aneurysms (Charcot-Bouchard microaneurysms )
- Form in vessels less than 300 μm in diameter.
Other CNS disorders caused by hypertension:
1. Lacunes or lacunar infarcts :
- Small cavitary infarcts, just a few millimeters in
size, and the main locations are:
a. In basal ganglia and thalamus
b. The internal capsule, and the pons.
- Are caused by occlusion of a single penetrating
vessel
2. Slit hemorrhages due to rupture of small
penetrating vessels and with time , these
hemorrhages resorb leaving slit-like cavities
surrounded by black discoloration
3.. Acute hypertensive encephalopathy :
- Most often is associated with sudden sustained
rises in diastolic blood pressure to greater than 130
mm Hg and characterized :
a. By increased intracranial pressure and
b Global cerebral dysfunction, manifesting as
headaches, confusion, vomiting, convulsions, and
sometimes coma.
- Rapid therapeutic intervention to reduce the intracranial pressure is essential.
2. Cerebral Amyloid Angiopathy (CAA) :
- Is the second most common cause of spontaneous
parenchymal hemorrhage
- Is a disease in which amyloidogenic peptides,
deposit in the walls of meningeal and cortical
vessels
- Amyloid deposition (Aβ amyloid) weakens vessel
walls and increases the risk of hemorrhages
- The hemorrhage differs in distribution from those
associated with hypertension